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Added PSU DS

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Signed-off-by: Bernardo Carvalho <bernardo.carvalho@tecnico.ulisboa.pt>
This commit is contained in:
Bernardo Brotas de Carvalho
2025-10-25 23:47:18 +01:00
parent edd9364f9f
commit cc8cab6d5f
3 changed files with 104 additions and 125 deletions
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4
Configurations/RTApp-2-Uart.cfg
View File

@@ -336,7 +336,7 @@ $TestApp = {
} }
} }
+UartOutDS = { +UartOutDS = {
Class = UARTOutput Class = PSUCommunicator::PSUCommunicatorTX
PortName = "/dev/ttyS0" //Name of the UART port, Mandatory PortName = "/dev/ttyS0" //Name of the UART port, Mandatory
//PortName = "/dev/ttyLoopWr" //Name of the UART port, Mandatory //PortName = "/dev/ttyLoopWr" //Name of the UART port, Mandatory
BaudRate = 9600 // 10.851 µs / Byte BaudRate = 9600 // 10.851 µs / Byte
@@ -344,6 +344,8 @@ $TestApp = {
Timeout = 200000 //Maximum time to wait for data Timeout = 200000 //Maximum time to wait for data
CPUMask = 8 //Affinity of the CPU of where to read data from CPUMask = 8 //Affinity of the CPU of where to read data from
SerialTimeout = 1000 SerialTimeout = 1000
PointOfZeroCurrent = 5.100000e+02
CurrentStep = 2.929700e+00
Signals = { Signals = {
SerialOut = { SerialOut = {
Type = float32 //Mandatory. Only type that is supported. Type = float32 //Mandatory. Only type that is supported.

181
DataSources/PSUCommunicator/PSUCommunicatorTX.cpp
View File

@@ -54,19 +54,14 @@ const float32 DAC_RANGE = 20.0;
// const float32 ATCA_IOP_MAX_DAC_RANGE = 20.0; // const float32 ATCA_IOP_MAX_DAC_RANGE = 20.0;
PSUCommunicatorTX::PSUCommunicatorTX() : DataSourceI(), MessageI() { PSUCommunicatorTX::PSUCommunicatorTX() : DataSourceI(), MessageI() {
// boardFileDescriptor = -1; // boardFileDescriptor = -1;
// numberOfDACsEnabled = 0u;
// isMaster = 0u;
// deviceName = "";
// boardId = 2u;
triggerSet = false; triggerSet = false;
uint32 n; uint32 n;
// for (n = 0u; n < ATCA_IOP_MAX_DAC_CHANNELS; n++) { // for (n = 0u; n < ATCA_IOP_MAX_DAC_CHANNELS; n++) {
// dacEnabled[n] = false; // dacEnabled[n] = false;
outputRange = DAC_RANGE;
//} //}
communicatorOnlineStage = FA_COMMUNICATOR_ONLINE_IDLE;
// channelsMemory = NULL_PTR(float32 *); // channelsMemory = NULL_PTR(float32 *);
channelValue = 0.0; // NULL_PTR(float32 *); currentValue = 0.0; // NULL_PTR(float32 *);
currentStep = 0.0; currentStep = 0.0;
pointOfZeroCurrent = 0.0; pointOfZeroCurrent = 0.0;
@@ -88,11 +83,6 @@ PSUCommunicatorTX::~PSUCommunicatorTX() {
serial.Close(); serial.Close();
REPORT_ERROR_PARAMETERS(ErrorManagement::Information, "Close %s OK.", REPORT_ERROR_PARAMETERS(ErrorManagement::Information, "Close %s OK.",
portName); portName);
/*
if (channelsMemory != NULL_PTR(float32 *)) {
delete[] channelsMemory;
}
*/
} }
bool PSUCommunicatorTX::AllocateMemory() { return true; } bool PSUCommunicatorTX::AllocateMemory() { return true; }
@@ -104,11 +94,9 @@ uint32 PSUCommunicatorTX::GetNumberOfMemoryBuffers() { return 1u; }
bool PSUCommunicatorTX::GetSignalMemoryBuffer(const uint32 signalIdx, bool PSUCommunicatorTX::GetSignalMemoryBuffer(const uint32 signalIdx,
const uint32 bufferIdx, const uint32 bufferIdx,
void *&signalAddress) { void *&signalAddress) {
bool ok = (signalIdx < (UART_MAX_CHANNELS)); bool ok = (signalIdx < (PSU_MAX_CHANNELS));
if (ok) { if (ok) {
// if (channelsMemory != NULL_PTR(float32 *)) { signalAddress = &currentValue;
signalAddress = &channelValue;
//}
} }
return ok; return ok;
} }
@@ -134,6 +122,7 @@ const char8 *PSUCommunicatorTX::GetBrokerName(StructuredDataI &data,
} }
return brokerName; return brokerName;
} }
bool PSUCommunicatorTX::GetInputBrokers(ReferenceContainer &inputBrokers, bool PSUCommunicatorTX::GetInputBrokers(ReferenceContainer &inputBrokers,
const char8 *const functionName, const char8 *const functionName,
void *const gamMemPtr) { void *const gamMemPtr) {
@@ -281,62 +270,6 @@ bool PSUCommunicatorTX::Initialise(StructuredDataI &data) {
"The port %s Not opened.", portName); "The port %s Not opened.", portName);
} }
// Get individual signal parameters
uint32 i = 0u;
if (ok) {
ok = data.MoveRelative("Signals");
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"Could not move to the Signals section");
}
// Do not allow to add signals in run-time
if (ok) {
ok = signalsDatabase.MoveRelative("Signals");
}
if (ok) {
ok = signalsDatabase.Write("Locked", 1u);
}
if (ok) {
ok = signalsDatabase.MoveToAncestor(1u);
}
// while ((i < ATCA_IOP_MAX_DAC_CHANNELS) && (ok)) {
if (data.MoveRelative(data.GetChildName(0))) {
// uint32 channelId;
float64 range;
ok = data.Read("OutputRange", range);
if (ok) {
// if (data.Read("OutputRange", range)) {
ok = (range > 0.0) && (range <= DAC_RANGE);
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"Invalid OutputRange specified.");
}
if (ok) {
outputRange = range;
REPORT_ERROR_PARAMETERS(ErrorManagement::Information,
" Parameter DAC Output Range %f", range);
// dacEnabled[i] = true;
// numberOfDACsEnabled++;
}
} else {
REPORT_ERROR(ErrorManagement::ParametersError,
"The OutputRange shall be specified.");
}
if (ok) {
ok = data.MoveToAncestor(1u);
}
}
}
if (ok) {
ok = data.MoveToAncestor(1u);
if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError,
"Could not move to the parent section");
}
}
// REPORT_ERROR_PARAMETERS(ErrorManagement::Information, "numberOfDACsEnabled
// %d", numberOfDACsEnabled);
return ok; return ok;
} }
@@ -352,12 +285,11 @@ bool PSUCommunicatorTX::SetConfiguredDatabase(StructuredDataI &data) {
"At least one Trigger signal shall be set."); "At least one Trigger signal shall be set.");
} }
if (ok) { if (ok) {
// for (i = 0u; (i < numberOfDACsEnabled) && (ok); i++) {
ok = (GetSignalType(0u) == Float32Bit); ok = (GetSignalType(0u) == Float32Bit);
//} //}
if (!ok) { if (!ok) {
REPORT_ERROR(ErrorManagement::ParametersError, REPORT_ERROR(ErrorManagement::ParametersError,
"All the DAC signals shall be of type Float32Bit"); "The PSU current signal shall be of type Float32Bit");
} }
} }
@@ -385,10 +317,12 @@ bool PSUCommunicatorTX::SetConfiguredDatabase(StructuredDataI &data) {
} }
// Create/Decode current packet // Create/Decode current packet
bool PSUCommunicatorTX::CreateCurrentPacket(float32 current, char8 *packet) { bool PSUCommunicatorTX::CreateCurrentPacket() {
bool ok = true;
// Calculate the point in the scale of the current // Calculate the point in the scale of the current
int16 pointOfCurrent = (int16)(pointOfZeroCurrent + current / currentStep); int16 pointOfCurrent =
(int16)(pointOfZeroCurrent + currentValue / currentStep);
// Saturate current // Saturate current
if (pointOfCurrent < FA_SCALE_MIN) if (pointOfCurrent < FA_SCALE_MIN)
@@ -402,33 +336,96 @@ bool PSUCommunicatorTX::CreateCurrentPacket(float32 current, char8 *packet) {
packet[0] = (char8)(0x0000 | ((nc & 0x03C0) >> 5) | ((pc & 0x0007) << 5)); packet[0] = (char8)(0x0000 | ((nc & 0x03C0) >> 5) | ((pc & 0x0007) << 5));
packet[1] = (char8)(0x0001 | ((pc & 0x03F8) >> 2)); packet[1] = (char8)(0x0001 | ((pc & 0x03F8) >> 2));
return true; return ok;
} }
bool PSUCommunicatorTX::SendMessage() {
bool ok = true;
serial.Write(packet, 2);
return ok;
}
bool PSUCommunicatorTX::CommunicatorOnline() {
bool ok = true;
switch (communicatorOnlineStage) {
case FA_COMMUNICATOR_ONLINE_IDLE:
// Log the entry on this stage
// if(this->communicatorOnlineIdleCount++ == 0)
// AssertErrorCondition(Information, "[FACom] COMMUNICATOR_ONLINE_IDLE");
break;
// Wait for the CODAC trigger
case FA_COMMUNICATOR_ONLINE_WAIT_CODAC_TRIGGER:
// Log the entry on this stage
// if(this->communicatorOnlineWaitTriggerCount++ == 0)
// AssertErrorCondition(Information, "[FACom]
// COMMUNICATOR_ONLINE_WAIT_CODAC_TRIGGER");
// if(IsTriggered)
//{
// Send Start Operation message
// this->SendMessage(FA_STARTOP_MESSAGE_1, FA_STARTOP_MESSAGE_2);
packet[0] = FA_STARTOP_MESSAGE_1;
packet[1] = FA_STARTOP_MESSAGE_2;
SendMessage();
// Increase attempts counter
// this->communicatorOnlineStartOperationAttempts++;
// Change online state
communicatorOnlineStage = FA_COMMUNICATOR_ONLINE_DISCHARGE;
// this->communicatorOnlineWaitTriggerCount = 0;
//}
break;
case FA_COMMUNICATOR_ONLINE_DISCHARGE:
/*
if(PlasmaEnded)
{
this->communicatorOnlineStage =
FA_COMMUNICATOR_ONLINE_STOP_OPERATION;
this->communicatorOnlineDischargeCount =
0; break;
}
*/
// CreateCurrentPacket(CurrentToSendCopy, packet1, packet2);
CreateCurrentPacket();
ok = SendMessage();
communicatorOnlineStage = FA_COMMUNICATOR_ONLINE_STOP_OPERATION;
break;
case FA_COMMUNICATOR_ONLINE_STOP_OPERATION:
packet[0] = FA_STARTOP_MESSAGE_1;
packet[1] = FA_STARTOP_MESSAGE_2;
ok = SendMessage();
break;
case FA_COMMUNICATOR_ONLINE_ERROR:
// AssertErrorCondition(InitialisationError, "[FACom]::%s Power supplies
// timeout: after %d attemps, FA_COMMUNICATOR_ONLINE_ERROR, RETURN FALSE",
// this->Name(), this->communicatorOnlineStopOperationAttempts);
ok = false;
break;
default:
break;
}
return ok;
}
bool PSUCommunicatorTX::Synchronise() { bool PSUCommunicatorTX::Synchronise() {
uint32 i; uint32 i;
int32 w = 24; int32 w = 24;
bool ok = true; bool ok = true;
char8 text[] = "ola"; // char8 text[] = "ola";
// if (channelsMemory != NULL_PTR(float32 *)) { // if (channelsMemory != NULL_PTR(float32 *)) {
// value = channelsMemory[0] / DAC_RANGE; // value = channelsMemory[0] / DAC_RANGE;
// for (i = 0u; (i < numberOfDACsEnabled ) && (ok); i++) {
int32 ser_value = channelValue / outputRange * 1000000.0;
REPORT_ERROR_PARAMETERS(ErrorManagement::Information, REPORT_ERROR_PARAMETERS(ErrorManagement::Information,
"Synchronise called. value: %f, %d", channelValue, "Synchronise called. value: %f", currentValue);
ser_value);
// w = SetDacReg(i, value); // w = SetDacReg(i, value);
char8 *data = reinterpret_cast<char8 *>(&ser_value); // char8 *data = reinterpret_cast<char8 *>(&ser_value);
serial.Write(data, sizeof(int32)); // serial.Write(data, sizeof(int32));
// serial.Write(text, 4); // serial.Write(text, 4);
// write(boardFileDescriptor, &w, 4);
// value = channelsMemory[1] / DAC_RANGE;
// value = channelsMemory[1] / DAC_RANGE * pow(2,17);
// w = SetDacReg(1, value);
// w = 0x000FFFFF & static_cast<uint32>(value);
// write(boardFileDescriptor, &w, 4);
// REPORT_ERROR(ErrorManagement::Information, " Writing DAC 0 0x%x", w);
/* /*
w = dacValues[i]; w = dacValues[i];

44
DataSources/PSUCommunicator/PSUCommunicatorTX.h
View File

@@ -36,6 +36,7 @@
/*---------------------------------------------------------------------------*/ /*---------------------------------------------------------------------------*/
/* Project header includes */ /* Project header includes */
/*---------------------------------------------------------------------------*/ /*---------------------------------------------------------------------------*/
#include "CLASSMETHODREGISTER.h"
#include "DataSourceI.h" #include "DataSourceI.h"
#include "EmbeddedServiceMethodBinderI.h" #include "EmbeddedServiceMethodBinderI.h"
#include "EventSem.h" #include "EventSem.h"
@@ -53,7 +54,7 @@ namespace MARTe {
* The number of signals * The number of signals
*/ */
const uint32 UART_MAX_CHANNELS = 1u; const uint32 PSU_MAX_CHANNELS = 1u;
/** /**
* @brief A DataSource which provides an analogue output interface to the ATCA * @brief A DataSource which provides an analogue output interface to the ATCA
@@ -70,7 +71,7 @@ const uint32 UART_MAX_CHANNELS = 1u;
* CurrentStep = * CurrentStep =
* PointOfZeroCurrent = * PointOfZeroCurrent =
* Signals = { * Signals = {
* SerialOut = { * CurrentSignal= {
* Type = float32//Mandatory. Only type that is supported. * Type = float32//Mandatory. Only type that is supported.
* OutputRange = 10.0 //Mandatory. The channel Module Output Range * OutputRange = 10.0 //Mandatory. The channel Module Output Range
in volt. in volt.
@@ -92,6 +93,7 @@ const uint32 UART_MAX_CHANNELS = 1u;
class PSUCommunicatorTX : public DataSourceI, public MessageI { class PSUCommunicatorTX : public DataSourceI, public MessageI {
public: public:
CLASS_REGISTER_DECLARATION() CLASS_REGISTER_DECLARATION()
// AtcaIopConfig ();
/** /**
* @brief Default constructor * @brief Default constructor
* @post * @post
@@ -191,7 +193,7 @@ public:
virtual bool SetConfiguredDatabase(StructuredDataI &data); virtual bool SetConfiguredDatabase(StructuredDataI &data);
/** /**
* @details Writes the value of all the DAC channels to the board. * @details Writes the packet to the PSU
* @return true if the writing of all the channels is successful. * @return true if the writing of all the channels is successful.
*/ */
virtual bool Synchronise(); virtual bool Synchronise();
@@ -201,14 +203,6 @@ private:
* The board device name * The board device name
*/ */
StreamString portName; StreamString portName;
/**
* The board identifier
*/
uint32 boardId;
/**
* The board file descriptor
*/
// int32 boardFileDescriptor;
/** /**
* The UART interface. * The UART interface.
*/ */
@@ -223,31 +217,14 @@ private:
*/ */
uint32 timeout; uint32 timeout;
/**
* DAC values
*/
// int32 dacValues[ATCA_IOP_N_DACs];
/** /**
* The signal memory * The signal memory
*/ */
float32 channelValue; float32 currentValue;
float32 currentStep; float32 currentStep;
float32 pointOfZeroCurrent; float32 pointOfZeroCurrent;
/** // Communicator online behaviour
* The DACs that are enabled uint32 communicatorOnlineStage;
*/
// bool dacEnabled[ATCA_IOP_MAX_DAC_CHANNELS];
/**
* The board individual channel output ranges
*/
float32 outputRange;
/**
* The number of enabled DACs
*/
uint32 numberOfDACsEnabled;
/** /**
* Filter to receive the RPC which allows to change the... * Filter to receive the RPC which allows to change the...
@@ -258,9 +235,12 @@ private:
* True if at least one trigger was set. * True if at least one trigger was set.
*/ */
bool triggerSet; bool triggerSet;
char8 packet[2];
// int32 SetDacReg(uint32 channel, float32 val) const; // int32 SetDacReg(uint32 channel, float32 val) const;
bool CreateCurrentPacket(float32 current, char8 *packet); bool SendMessage();
bool CommunicatorOnline();
bool CreateCurrentPacket(); // float32 current, char8 *packet);
}; };
} // namespace MARTe } // namespace MARTe